stm32f1xx-hal
HAL for the STM32F1 family of microcontrollers
Quick start guide
Embedded Rust development requires a bit more setup than ordinary development. For this guide, we'll assume you're using a stm32 blue pill board (shown below), but if you have another f1 microcontroller, you should be able to adapt it.
You will also need a debug probe, for example an stlink v3 mini for programming and debugging. (There are many different STLink probes out there, all of them should work fine with the instructions given here, other JTAG or SWD debug probes will work as well but will need different software or configuration).
Installing software
To program your microcontroller, you need to install:
- openocd
gdb-multiarch
(on some platforms you may need to usegdb-arm-none-eabi
instead, make sure to update.cargo/config
to reflect this change)
Finally, you need to install arm target support for the Rust compiler. To do so, run
rustup target install thumbv7m-none-eabi
Setting up your project
Create a new Rust project as you usually do with cargo init
. The hello world
of embedded development is usually to blink an LED and code to do so is
available in examples/blinky.rs. Copy that file to the
main.rs
of your project.
You also need to add some dependencies to your Cargo.toml
:
[dependencies]
embedded-hal = "0.2.3"
nb = "0.1.2"
cortex-m = "0.6.2"
cortex-m-rt = "0.6.11"
# Panic behaviour, see https://crates.io/keywords/panic-impl for alternatives
panic-halt = "0.2.0"
[dependencies.stm32f1xx-hal]
version = "0.6.1"
features = ["rt", "stm32f103", "medium"]
If you build your project now, you should get a single error: error: language item required, but not found: eh_personality
. This unhelpful error message
is fixed by compiling for the right target.
We also need to tell Rust how to link our executable, and how to lay out the result in memory. To accomplish all this, copy .cargo/config and memory.x from the stm32f1xx-hal repo to your project.
cargo build
If everything went well, your project should have built without errors.
Programming the microcontroller
It is now time to actually run the code on the hardware. To do so plug your
debug probe into the blue pill and start openocd
using
openocd -f interface/stlink-v3.cfg -f target/stm32f1x.cfg
If you are not using an stlink V3, change the interface accordingly. For more information, see the embeddonomicon.
If all went well, it should detect your microcontroller and say Info : stm32f1x.cpu: hardware has 6 breakpoints, 4 watchpoints
. Keep it running in
the background.
We will use gdb for uploading the compiled binary to the microcontroller and
for debugging. Cargo will automatically start gdb
thanks to the
.cargo/config you added earlier. gdb
also needs to be told
to connect to openocd which is done by copying .gdbinit to the root
of your project.
You may also need to tell gdb
that it is safe to load .gdbinit
from the
working directory.
- Linux
echo "set auto-load safe-path $(pwd)" >> ~/.gdbinit
- Windows
echo set auto-load safe-path %CD% >> %USERPROFILE%\.gdbinit
If everything was successful, cargo should compile your project, start gdb,
load your program and give you a prompt. If you type continue
in the gdb
prompt, your program should start and the green led on the blue pill should
start blinking.
Going further
From here on, you can start adding more code to your project to make it do something more interesting. For crate documentation, see docs.rs/stm32f1xx-hal. There are also a lot more examples available. If something is unclear in the docs or examples, please, open an issue and we will try to improve it.
Selecting a microcontroller
This crate supports multiple microcontrollers in the
stm32f1 family. Which specific microcontroller you want to build for has to be
specified with a feature, for example stm32f103
.
If no microcontroller is specified, the crate will not compile.
You may also need to specify the density of the device with medium
, high
or xl
to enable certain peripherals. Generally the density can be determined by the 2nd character
after the number in the device name (i.e. For STM32F103C6U, the 6 indicates a low-density
device) but check the datasheet or CubeMX to be sure.
- 4, 6 => low density, no feature required
- 8, B =>
medium
feature - C, D, E =>
high
feature - F, G =>
xl
feature
For microcontrollers of the connectivity line
(stm32f105
and stm32f107
) no
density feature must be specified.
Supported Microcontrollers
stm32f100
stm32f101
stm32f103
stm32f105
stm32f107
Trying out the examples
You may need to give cargo
permission to call gdb
from the working directory.
- Linux
echo "set auto-load safe-path $(pwd)" >> ~/.gdbinit
- Windows
echo set auto-load safe-path %CD% >> %USERPROFILE%\.gdbinit
Compile, load, and launch the hardware debugger.
$ rustup target add thumbv7m-none-eabi
# on another terminal
$ openocd -f interface/$INTERFACE.cfg -f target/stm32f1x.cfg
# flash and debug the "Hello, world" example. Change stm32f103 to match your hardware
$ cargo run --features stm32f103 --example hello
$INTERFACE
should be set based on your debugging hardware. If you are using
an stlink V2, use stlink-v2.cfg
. For more information, see the
embeddonomicon.
Using as a Dependency
When using this crate as a dependency in your project, the microcontroller can
be specified as part of the Cargo.toml
definition.
[dependencies.stm32f1xx-hal]
version = "0.6.1"
features = ["stm32f100", "rt"]
Documentation
The documentation can be found at docs.rs.
License
Licensed under either of
- Apache License, Version 2.0 (LICENSE-APACHE or http://www.apache.org/licenses/LICENSE-2.0)
- MIT license (LICENSE-MIT or http://opensource.org/licenses/MIT)
at your option.
Contribution
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.